ch3u_rma_sync.c 59.4 KB
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/* -*- Mode: C; c-basic-offset:4 ; indent-tabs-mode:nil ; -*- */
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/*
 *  (C) 2001 by Argonne National Laboratory.
 *      See COPYRIGHT in top-level directory.
 */

#include "mpidimpl.h"
#include "mpidrma.h"

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/* Notes for memory barriers in RMA synchronizations

   When SHM is allocated for RMA window, we need to add memory berriers at proper
   places in RMA synchronization routines to guarantee the ordering of read/write
   operations, so that any operations after synchronization calls will see the
   correct data.

   There are four kinds of operations involved in the following explanation:

   1. Local loads/stores: any operations happening outside RMA epoch and accessing
      each process's own window memory.

   2. SHM operations: any operations happening inside RMA epoch. They may access
      any processes' window memory, which include direct loads/stores, and
      RMA operations that are internally implemented as direct loads/stores in
      MPI implementation.

   3. PROC_SYNC: synchronzations among processes by sending/recving messages.

   4. MEM_SYNC: a full memory barrier. It ensures the ordering of read/write
      operations on each process.

   (1) FENCE synchronization

              RANK 0                           RANK 1

       (local loads/stores)             (local loads/stores)

           WIN_FENCE {                    WIN_FENCE {
               MEM_SYNC                       MEM_SYNC
               PROC_SYNC -------------------- PROC_SYNC
               MEM_SYNC                       MEM_SYNC
           }                              }

        (SHM operations)                  (SHM operations)

           WIN_FENCE {                     WIN_FENCE {
               MEM_SYNC                        MEM_SYNC
               PROC_SYNC --------------------- PROC_SYNC
               MEM_SYNC                        MEM_SYNC
           }                               }

      (local loads/stores)              (local loads/stores)

       We need MEM_SYNC before and after PROC_SYNC for both starting WIN_FENCE
       and ending WIN_FENCE, to ensure the ordering between local loads/stores
       and PROC_SYNC in starting WIN_FENCE (and vice versa in ending WIN_FENCE),
       and the ordering between PROC_SYNC and SHM operations in starting WIN_FENCE
       (and vice versa for ending WIN_FENCE).

       In starting WIN_FENCE, the MEM_SYNC before PROC_SYNC essentially exposes
       previous local loads/stores to other processes; after PROC_SYNC, each
       process knows that everyone else already exposed their local loads/stores;
       the MEM_SYNC after PROC_SYNC ensures that my following SHM operations will
       happen after PROC_SYNC and will see the latest data on other processes.

       In ending WIN_FENCE, the MEM_SYNC before PROC_SYNC essentially exposes
       previous SHM operations to other processes; after PROC_SYNC, each process
       knows everyone else already exposed their SHM operations; the MEM_SYNC
       after PROC_SYNC ensures that my following local loads/stores will happen
       after PROC_SYNC and will see the latest data in my memory region.

   (2) POST-START-COMPLETE-WAIT synchronization

              RANK 0                           RANK 1

                                          (local loads/stores)

           WIN_START {                      WIN_POST {
                                                MEM_SYNC
               PROC_SYNC ---------------------- PROC_SYNC
               MEM_SYNC
           }                                }

         (SHM operations)

           WIN_COMPLETE {                  WIN_WAIT/TEST {
               MEM_SYNC
               PROC_SYNC --------------------- PROC_SYNC
                                               MEM_SYNC
           }                               }

                                          (local loads/stores)

       We need MEM_SYNC before PROC_SYNC for WIN_POST and WIN_COMPLETE, and
       MEM_SYNC after PROC_SYNC in WIN_START and WIN_WAIT/TEST, to ensure the
       ordering between local loads/stores and PROC_SYNC in WIN_POST (and
       vice versa in WIN_WAIT/TEST), and the ordering between PROC_SYNC and SHM
       operations in WIN_START (and vice versa in WIN_COMPLETE).

       In WIN_POST, the MEM_SYNC before PROC_SYNC essentially exposes previous
       local loads/stores to group of origin processes; after PROC_SYNC, origin
       processes knows all target processes already exposed their local
       loads/stores; in WIN_START, the MEM_SYNC after PROC_SYNC ensures that
       following SHM operations will happen after PROC_SYNC and will see the
       latest data on target processes.

       In WIN_COMPLETE, the MEM_SYNC before PROC_SYNC essentailly exposes previous
       SHM operations to group of target processes; after PROC_SYNC, target
       processes knows all origin process already exposed their SHM operations;
       in WIN_WAIT/TEST, the MEM_SYNC after PROC_SYNC ensures that following local
       loads/stores will happen after PROC_SYNC and will see the latest data in
       my memory region.

   (3) Passive target synchronization

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                                        WIN_LOCK(target=1) {
                                            PROC_SYNC (lock granted)
                                            MEM_SYNC
                                        }

                                        (SHM operations)

                                        WIN_UNLOCK(target=1) {
                                            MEM_SYNC
                                            PROC_SYNC (lock released)
                                        }

         PROC_SYNC -------------------- PROC_SYNC

         WIN_LOCK (target=1) {
             PROC_SYNC (lock granted)
             MEM_SYNC
         }

         (SHM operations)

         WIN_UNLOCK (target=1) {
             MEM_SYNC
             PROC_SYNC (lock released)
         }

         PROC_SYNC -------------------- PROC_SYNC

                                        WIN_LOCK(target=1) {
                                            PROC_SYNC (lock granted)
                                            MEM_SYNC
                                        }

                                        (SHM operations)

                                        WIN_UNLOCK(target=1) {
                                            MEM_SYNC
                                            PROC_SYNC (lock released)
                                        }

         We need MEM_SYNC after PROC_SYNC in WIN_LOCK, and MEM_SYNC before
         PROC_SYNC in WIN_UNLOCK, to ensure the ordering between SHM operations
         and PROC_SYNC and vice versa.

         In WIN_LOCK, the MEM_SYNC after PROC_SYNC guarantees two things:
         (a) it guarantees that following SHM operations will happen after
         lock is granted; (b) it guarantees that following SHM operations
         will happen after any PROC_SYNC with target before WIN_LOCK is called,
         which means those SHM operations will see the latest data on target
         process.

         In WIN_UNLOCK, the MEM_SYNC before PROC_SYNC also guarantees two
         things: (a) it guarantees that SHM operations will happen before
         lock is released; (b) it guarantees that SHM operations will happen
         before any PROC_SYNC with target after WIN_UNLOCK is returned, which
         means following SHM operations on that target will see the latest data.

         WIN_LOCK_ALL/UNLOCK_ALL are same with WIN_LOCK/UNLOCK.

              RANK 0                          RANK 1

         WIN_LOCK_ALL

         (SHM operations)

         WIN_FLUSH(target=1) {
             MEM_SYNC
         }

         PROC_SYNC ------------------------PROC_SYNC

                                           WIN_LOCK(target=1) {
                                               PROC_SYNC (lock granted)
                                               MEM_SYNC
                                           }

                                           (SHM operations)

                                           WIN_UNLOCK(target=1) {
                                               MEM_SYNC
                                               PROC_SYNC (lock released)
                                           }

         WIN_UNLOCK_ALL

         We need MEM_SYNC in WIN_FLUSH to ensure the ordering between SHM
         operations and PROC_SYNC.

         The MEM_SYNC in WIN_FLUSH guarantees that all SHM operations before
         this WIN_FLUSH will happen before any PROC_SYNC with target after
         this WIN_FLUSH, which means SHM operations on target process after
         PROC_SYNC with origin will see the latest data.
*/

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MPIR_T_PVAR_DOUBLE_TIMER_DECL(RMA, rma_lockqueue_alloc);
MPIR_T_PVAR_DOUBLE_TIMER_DECL(RMA, rma_winlock_getlocallock);
MPIR_T_PVAR_DOUBLE_TIMER_DECL(RMA, rma_wincreate_allgather);

MPIR_T_PVAR_DOUBLE_TIMER_DECL(RMA, rma_rmaqueue_alloc);
MPIR_T_PVAR_DOUBLE_TIMER_DECL(RMA, rma_rmaqueue_set);

void MPIDI_CH3_RMA_Init_sync_pvars(void)
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{
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    /* rma_lockqueue_alloc */
    MPIR_T_PVAR_TIMER_REGISTER_STATIC(RMA,
                                      MPI_DOUBLE,
                                      rma_lockqueue_alloc,
                                      MPI_T_VERBOSITY_MPIDEV_DETAIL,
                                      MPI_T_BIND_NO_OBJECT,
                                      MPIR_T_PVAR_FLAG_READONLY,
                                      "RMA", "Allocate Lock Queue element (in seconds)");

    /* rma_winlock_getlocallock */
    MPIR_T_PVAR_TIMER_REGISTER_STATIC(RMA,
                                      MPI_DOUBLE,
                                      rma_winlock_getlocallock,
                                      MPI_T_VERBOSITY_MPIDEV_DETAIL,
                                      MPI_T_BIND_NO_OBJECT,
                                      MPIR_T_PVAR_FLAG_READONLY,
                                      "RMA", "WIN_LOCK:Get local lock (in seconds)");

    /* rma_wincreate_allgather */
    MPIR_T_PVAR_TIMER_REGISTER_STATIC(RMA,
                                      MPI_DOUBLE,
                                      rma_wincreate_allgather,
                                      MPI_T_VERBOSITY_MPIDEV_DETAIL,
                                      MPI_T_BIND_NO_OBJECT,
                                      MPIR_T_PVAR_FLAG_READONLY,
                                      "RMA", "WIN_CREATE:Allgather (in seconds)");

    /* rma_rmaqueue_alloc */
    MPIR_T_PVAR_TIMER_REGISTER_STATIC(RMA,
                                      MPI_DOUBLE,
                                      rma_rmaqueue_alloc,
                                      MPI_T_VERBOSITY_MPIDEV_DETAIL,
                                      MPI_T_BIND_NO_OBJECT,
                                      MPIR_T_PVAR_FLAG_READONLY,
                                      "RMA", "Allocate RMA Queue element (in seconds)");

    /* rma_rmaqueue_set */
    MPIR_T_PVAR_TIMER_REGISTER_STATIC(RMA,
                                      MPI_DOUBLE,
                                      rma_rmaqueue_set,
                                      MPI_T_VERBOSITY_MPIDEV_DETAIL,
                                      MPI_T_BIND_NO_OBJECT,
                                      MPIR_T_PVAR_FLAG_READONLY,
                                      "RMA", "Set fields in RMA Queue element (in seconds)");
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}
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/* These are used to use a common routine to complete lists of RMA
   operations with a single routine, while collecting data that
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   distinguishes between different synchronization modes.  This is not
   thread-safe; the best choice for thread-safety is to eliminate this
   ability to discriminate between the different types of RMA synchronization.
*/
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/*
 * These routines provide a default implementation of the MPI RMA operations
 * in terms of the low-level, two-sided channel operations.  A channel
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 * may override these functions, on a per-window basis, by overriding
 * the MPID functions in the RMAFns section of MPID_Win object.
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 */

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#define SYNC_POST_TAG 100

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/********************************************************************************/
/* Active Target synchronization (including WIN_FENCE, WIN_POST, WIN_START,     */
/* WIN_COMPLETE, WIN_WAIT, WIN_TEST)                                            */
/********************************************************************************/

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#undef FUNCNAME
#define FUNCNAME MPIDI_Win_fence
#undef FCNAME
#define FCNAME MPIDI_QUOTE(FUNCNAME)
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int MPIDI_Win_fence(int assert, MPID_Win * win_ptr)
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{
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    int i, made_progress = 0;
    int local_completed = 0, remote_completed = 0;
    MPIDI_RMA_Target_t *curr_target = NULL;
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    mpir_errflag_t errflag = MPIR_ERR_NONE;
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    int mpi_errno = MPI_SUCCESS;
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    MPIDI_STATE_DECL(MPID_STATE_MPIDI_WIN_FENCE);

    MPIDI_RMA_FUNC_ENTER(MPID_STATE_MPIDI_WIN_FENCE);

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    MPIU_ERR_CHKANDJUMP((win_ptr->states.access_state != MPIDI_RMA_NONE &&
                         win_ptr->states.access_state != MPIDI_RMA_FENCE_ISSUED &&
                         win_ptr->states.access_state != MPIDI_RMA_FENCE_GRANTED) ||
                        win_ptr->states.exposure_state != MPIDI_RMA_NONE,
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                        mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");

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    win_ptr->posted_ops_cnt = 0;
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    if (assert & MPI_MODE_NOPRECEDE) {
        if (assert & MPI_MODE_NOSUCCEED) {
            goto fn_exit;
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        }
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        else {
            /* It is possible that there is a IBARRIER in MPI_WIN_FENCE with
               MODE_NOPRECEDE not being completed, we let the progress engine
               to delete its request when it is completed. */
            if (win_ptr->fence_sync_req != MPI_REQUEST_NULL) {
                MPID_Request *req_ptr;
                MPID_Request_get_ptr(win_ptr->fence_sync_req, req_ptr);
                MPID_Request_release(req_ptr);
                win_ptr->fence_sync_req = MPI_REQUEST_NULL;
                win_ptr->states.access_state = MPIDI_RMA_NONE;
            }
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            if (win_ptr->shm_allocated == TRUE) {
                MPID_Comm *node_comm_ptr = win_ptr->comm_ptr->node_comm;
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                /* Ensure ordering of load/store operations. */
                OPA_read_write_barrier();
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                mpi_errno = MPIR_Barrier_impl(node_comm_ptr, &errflag);
                if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
                MPIU_ERR_CHKANDJUMP(errflag, mpi_errno, MPI_ERR_OTHER, "**coll_fail");
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                /* Ensure ordering of load/store operations. */
                OPA_read_write_barrier();
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            }

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            mpi_errno = MPIR_Ibarrier_impl(win_ptr->comm_ptr, &(win_ptr->fence_sync_req));
            if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
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            win_ptr->states.access_state = MPIDI_RMA_FENCE_ISSUED;
            num_active_issued_win++;
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            goto fn_exit;
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        }
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    }
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    if (win_ptr->states.access_state == MPIDI_RMA_FENCE_ISSUED) {
        while (win_ptr->states.access_state != MPIDI_RMA_FENCE_GRANTED) {
            mpi_errno = wait_progress_engine();
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            if (mpi_errno != MPI_SUCCESS)
                MPIU_ERR_POP(mpi_errno);
        }
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    }
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    /* Set sync_flag in target structs. */
    for (i = 0; i < win_ptr->num_slots; i++) {
        curr_target = win_ptr->slots[i].target_list;
        while (curr_target != NULL) {

            /* set sync_flag in sync struct */
            if (curr_target->sync.sync_flag < MPIDI_RMA_SYNC_FLUSH) {
                curr_target->sync.sync_flag = MPIDI_RMA_SYNC_FLUSH;
                curr_target->sync.have_remote_incomplete_ops = 0;
                curr_target->sync.outstanding_acks++;
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            }
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            curr_target = curr_target->next;
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        }
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    }
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    /* Issue out all operations. */
    mpi_errno = MPIDI_CH3I_RMA_Make_progress_win(win_ptr, &made_progress);
    if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);

    /* Wait for remote completion. */
    do {
        mpi_errno = MPIDI_CH3I_RMA_Cleanup_ops_win(win_ptr,
                                                   &local_completed,
                                                   &remote_completed);
        if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
        if (!remote_completed) {
            mpi_errno = wait_progress_engine();
            if (mpi_errno != MPI_SUCCESS)
                MPIU_ERR_POP(mpi_errno);
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        }
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    } while (!remote_completed);
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    /* Cleanup all targets on window. */
    mpi_errno = MPIDI_CH3I_RMA_Cleanup_targets_win(win_ptr);
    if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
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    MPIU_Assert(win_ptr->non_empty_slots == 0);
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    /* Ensure ordering of load/store operations. */
    if (win_ptr->shm_allocated == TRUE) {
        OPA_read_write_barrier();
    }
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    mpi_errno = MPIR_Barrier_impl(win_ptr->comm_ptr, &errflag);
    if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
    MPIU_ERR_CHKANDJUMP(errflag, mpi_errno, MPI_ERR_OTHER, "**coll_fail");
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    /* Ensure ordering of load/store operations. */
    if (win_ptr->shm_allocated == TRUE) {
        OPA_read_write_barrier();
    }
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    if (assert & MPI_MODE_NOSUCCEED) {
        win_ptr->states.access_state = MPIDI_RMA_NONE;
    }
    else {
        win_ptr->states.access_state = MPIDI_RMA_FENCE_GRANTED;
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    }

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    /* There should be no active requests. */
    MPIU_Assert(win_ptr->active_req_cnt == 0);

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  fn_exit:
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    MPIDI_RMA_FUNC_EXIT(MPID_STATE_MPIDI_WIN_FENCE);
    return mpi_errno;
    /* --BEGIN ERROR HANDLING-- */
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  fn_fail:
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    goto fn_exit;
    /* --END ERROR HANDLING-- */
}


#undef FUNCNAME
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#define FUNCNAME MPIDI_Win_post
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#undef FCNAME
#define FCNAME MPIDI_QUOTE(FUNCNAME)
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int MPIDI_Win_post(MPID_Group * post_grp_ptr, int assert, MPID_Win * win_ptr)
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{
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    int *post_ranks_in_win_grp;
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    int mpi_errno = MPI_SUCCESS;
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    MPIU_CHKLMEM_DECL(3);
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    MPIDI_STATE_DECL(MPID_STATE_MPIDI_WIN_POST);
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    MPIDI_RMA_FUNC_ENTER(MPID_STATE_MPIDI_WIN_POST);
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    /* Note that here we cannot distinguish if this exposure epoch is overlapped
       with an exposure epoch of FENCE (which is not allowed), since FENCE may be
       ended up with not unsetting the window state. We can only detect if this
       exposure epoch is overlapped with another exposure epoch of PSCW. */
    MPIU_ERR_CHKANDJUMP(win_ptr->states.exposure_state != MPIDI_RMA_NONE,
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                        mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");
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    win_ptr->states.exposure_state = MPIDI_RMA_PSCW_EXPO;
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    win_ptr->at_completion_counter += post_grp_ptr->size;
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    /* Ensure ordering of load/store operations. */
    if (win_ptr->shm_allocated == TRUE) {
        OPA_read_write_barrier();
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    }

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    if ((assert & MPI_MODE_NOCHECK) == 0) {
        MPI_Request *req;
        MPI_Status *status;
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        int i, post_grp_size, dst, rank;
        MPID_Comm *win_comm_ptr;
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        /* NOCHECK not specified. We need to notify the source
         * processes that Post has been called. */
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        post_grp_size = post_grp_ptr->size;
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        win_comm_ptr = win_ptr->comm_ptr;
        rank = win_ptr->comm_ptr->rank;
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        MPIU_CHKLMEM_MALLOC(post_ranks_in_win_grp, int *,
                            post_grp_size * sizeof(int), mpi_errno, "post_ranks_in_win_grp");
        mpi_errno = fill_ranks_in_win_grp(win_ptr, post_grp_ptr, post_ranks_in_win_grp);
        if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);

        MPIU_CHKLMEM_MALLOC(req, MPI_Request *, post_grp_size * sizeof(MPI_Request),
                            mpi_errno, "req");
        MPIU_CHKLMEM_MALLOC(status, MPI_Status *, post_grp_size * sizeof(MPI_Status),
                            mpi_errno, "status");
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        /* Send a 0-byte message to the source processes */
        for (i = 0; i < post_grp_size; i++) {
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            dst = post_ranks_in_win_grp[i];
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            if (dst != rank) {
                MPID_Request *req_ptr;
                mpi_errno = MPID_Isend(&i, 0, MPI_INT, dst, SYNC_POST_TAG, win_comm_ptr,
                                       MPID_CONTEXT_INTRA_PT2PT, &req_ptr);
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                if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
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                req[i] = req_ptr->handle;
            }
            else {
                req[i] = MPI_REQUEST_NULL;
            }
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        }
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        mpi_errno = MPIR_Waitall_impl(post_grp_size, req, status);
        if (mpi_errno && mpi_errno != MPI_ERR_IN_STATUS)
            MPIU_ERR_POP(mpi_errno);

        /* --BEGIN ERROR HANDLING-- */
        if (mpi_errno == MPI_ERR_IN_STATUS) {
            for (i = 0; i < post_grp_size; i++) {
                if (status[i].MPI_ERROR != MPI_SUCCESS) {
                    mpi_errno = status[i].MPI_ERROR;
                    MPIU_ERR_POP(mpi_errno);
                }
            }
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        }
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        /* --END ERROR HANDLING-- */
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    }
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  fn_exit:
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    MPIU_CHKLMEM_FREEALL();
    MPIDI_RMA_FUNC_EXIT(MPID_STATE_MPIDI_WIN_POST);
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    return mpi_errno;
    /* --BEGIN ERROR HANDLING-- */
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  fn_fail:
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    goto fn_exit;
    /* --END ERROR HANDLING-- */
}

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#undef FUNCNAME
#define FUNCNAME MPIDI_Win_start
#undef FCNAME
#define FCNAME MPIDI_QUOTE(FUNCNAME)
int MPIDI_Win_start(MPID_Group * group_ptr, int assert, MPID_Win * win_ptr)
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{
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    int mpi_errno = MPI_SUCCESS;
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    MPIU_CHKLMEM_DECL(2);
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    MPIU_CHKPMEM_DECL(2);
    MPIDI_STATE_DECL(MPID_STATE_MPIDI_WIN_START);
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    MPIDI_RMA_FUNC_ENTER(MPID_STATE_MPIDI_WIN_START);
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    /* Note that here we cannot distinguish if this access epoch is overlapped
       with an access epoch of FENCE (which is not allowed), since FENCE may be
       ended up with not unsetting the window state. We can only detect if this
       access epoch is overlapped with another access epoch of PSCW or Passive
       Target. */
    MPIU_ERR_CHKANDJUMP(win_ptr->states.access_state != MPIDI_RMA_NONE &&
                        win_ptr->states.access_state != MPIDI_RMA_FENCE_ISSUED &&
                        win_ptr->states.access_state != MPIDI_RMA_FENCE_GRANTED,
                        mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");
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    win_ptr->start_grp_size = group_ptr->size;
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    if ((assert & MPI_MODE_NOCHECK) == 0) {
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        int i, intra_cnt;
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        MPI_Request *intra_start_req = NULL;
        MPI_Status *intra_start_status = NULL;
        MPID_Comm *comm_ptr = win_ptr->comm_ptr;
        int rank = comm_ptr->rank;

        /* wait for messages from local processes */
        MPIU_CHKPMEM_MALLOC(win_ptr->start_ranks_in_win_grp, int *, win_ptr->start_grp_size * sizeof(int),
                            mpi_errno, "win_ptr->start_ranks_in_win_grp");
        mpi_errno = fill_ranks_in_win_grp(win_ptr, group_ptr, win_ptr->start_ranks_in_win_grp);
        if (mpi_errno) MPIU_ERR_POP(mpi_errno);
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        /* post IRECVs */
        MPIU_CHKPMEM_MALLOC(win_ptr->start_req, MPI_Request *,
                            win_ptr->start_grp_size * sizeof(MPI_Request),
                            mpi_errno, "win_ptr->start_req");
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        if (win_ptr->shm_allocated == TRUE) {
            int node_comm_size = comm_ptr->node_comm->local_size;
            MPIU_CHKLMEM_MALLOC(intra_start_req, MPI_Request *,
                                node_comm_size * sizeof(MPI_Request),
                                mpi_errno, "intra_start_req");
            MPIU_CHKLMEM_MALLOC(intra_start_status, MPI_Status *,
                                node_comm_size * sizeof(MPI_Status),
                                mpi_errno, "intra_start_status");
        }
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        intra_cnt = 0;
        for (i = 0; i < win_ptr->start_grp_size; i++) {
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            MPID_Request *req_ptr;
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            MPIDI_VC_t *orig_vc = NULL, *target_vc = NULL;
            int src = win_ptr->start_ranks_in_win_grp[i];
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            if (src != rank) {
                MPIDI_Comm_get_vc(comm_ptr, rank, &orig_vc);
                MPIDI_Comm_get_vc(comm_ptr, src, &target_vc);
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                mpi_errno = MPID_Irecv(NULL, 0, MPI_INT, src, SYNC_POST_TAG,
                                       comm_ptr, MPID_CONTEXT_INTRA_PT2PT, &req_ptr);
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                if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
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                if (win_ptr->shm_allocated == TRUE &&
                    orig_vc->node_id == target_vc->node_id) {
                    intra_start_req[intra_cnt++] = req_ptr->handle;
                    win_ptr->start_req[i] = MPI_REQUEST_NULL;
                }
                else {
                    win_ptr->start_req[i] = req_ptr->handle;
                }
            }
            else {
                win_ptr->start_req[i] = MPI_REQUEST_NULL;
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            }
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        }
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        /* for targets on SHM, waiting until their IRECVs to be finished */
        if (intra_cnt) {
            mpi_errno = MPIR_Waitall_impl(intra_cnt, intra_start_req, intra_start_status);
            if (mpi_errno && mpi_errno != MPI_ERR_IN_STATUS)
                MPIU_ERR_POP(mpi_errno);
            /* --BEGIN ERROR HANDLING-- */
            if (mpi_errno == MPI_ERR_IN_STATUS) {
                for (i = 0; i < intra_cnt; i++) {
                    if (intra_start_status[i].MPI_ERROR != MPI_SUCCESS) {
                        mpi_errno = intra_start_status[i].MPI_ERROR;
                        MPIU_ERR_POP(mpi_errno);
                    }
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                }
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            }
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            /* --END ERROR HANDLING-- */
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        }
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        if (win_ptr->shm_allocated == TRUE) {
            /* Ensure ordering of load/store operations */
            OPA_read_write_barrier();
        }
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    }

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    win_ptr->states.access_state = MPIDI_RMA_PSCW_ISSUED;
    num_active_issued_win++;
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    MPIU_Assert(win_ptr->posted_ops_cnt == 0);
    MPIU_Assert(win_ptr->active_req_cnt == 0);
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 fn_exit:
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    MPIU_CHKLMEM_FREEALL();
    MPIDI_RMA_FUNC_EXIT(MPID_STATE_MPIDI_WIN_START);
    return mpi_errno;
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 fn_fail:
    MPIU_CHKPMEM_REAP();
    goto fn_exit;
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}


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#undef FUNCNAME
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#define FUNCNAME MPIDI_Win_complete
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#undef FCNAME
#define FCNAME MPIDI_QUOTE(FUNCNAME)
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int MPIDI_Win_complete(MPID_Win * win_ptr)
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{
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    int mpi_errno = MPI_SUCCESS;
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    int i, dst, rank = win_ptr->comm_ptr->rank;
    int local_completed = 0, remote_completed = 0;
    MPID_Comm *win_comm_ptr = win_ptr->comm_ptr;
    MPIDI_RMA_Target_t *curr_target;
    int made_progress;
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    MPIDI_STATE_DECL(MPID_STATE_MPIDI_WIN_COMPLETE);
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    MPIDI_RMA_FUNC_ENTER(MPID_STATE_MPIDI_WIN_COMPLETE);
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    /* Access epochs on the same window must be disjoint. */
    MPIU_ERR_CHKANDJUMP(win_ptr->states.access_state != MPIDI_RMA_PSCW_ISSUED &&
                        win_ptr->states.access_state != MPIDI_RMA_PSCW_GRANTED,
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James Dinan committed
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                        mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");

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    if (win_ptr->states.access_state == MPIDI_RMA_PSCW_ISSUED) {
        while (win_ptr->states.access_state != MPIDI_RMA_PSCW_GRANTED) {
            mpi_errno = wait_progress_engine();
            if (mpi_errno != MPI_SUCCESS)
                MPIU_ERR_POP(mpi_errno);
        }
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    }

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    for (i = 0; i < win_ptr->start_grp_size; i++) {
        dst = win_ptr->start_ranks_in_win_grp[i];
        if (dst == rank) {
            win_ptr->at_completion_counter--;
            MPIU_Assert(win_ptr->at_completion_counter >= 0);
            continue;
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        }
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        if (win_comm_ptr->local_size <= win_ptr->num_slots)
            curr_target = win_ptr->slots[dst].target_list;
        else {
            curr_target = win_ptr->slots[dst % win_ptr->num_slots].target_list;
            while (curr_target != NULL && curr_target->target_rank != dst)
                curr_target = curr_target->next;
        }
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        if (curr_target != NULL) {
            /* set sync_flag in sync struct */
            if (curr_target->sync.sync_flag < MPIDI_RMA_SYNC_FLUSH) {
                curr_target->sync.sync_flag = MPIDI_RMA_SYNC_FLUSH;
                curr_target->sync.have_remote_incomplete_ops = 0;
                curr_target->sync.outstanding_acks++;
            }
            curr_target->win_complete_flag = 1;
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        }
        else {
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            /* FIXME: do we need to wait for remote completion? */
            mpi_errno = send_decr_at_cnt_msg(dst, win_ptr);
            if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
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        }
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    }

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    /* issue out all operations */
    mpi_errno = MPIDI_CH3I_RMA_Make_progress_win(win_ptr, &made_progress);
    if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);

    /* wait until all slots are empty */
    do {
        mpi_errno = MPIDI_CH3I_RMA_Cleanup_ops_win(win_ptr, &local_completed,
                                                   &remote_completed);
        if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
        if (!remote_completed) {
            mpi_errno = wait_progress_engine();
            if (mpi_errno != MPI_SUCCESS)
                MPIU_ERR_POP(mpi_errno);
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        }
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    } while (!remote_completed);
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    /* Cleanup all targets on this window. */
    mpi_errno = MPIDI_CH3I_RMA_Cleanup_targets_win(win_ptr);
    if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
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    MPIU_Assert(win_ptr->non_empty_slots == 0);
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    /* Ensure ordering of load/store operations. */
    if (win_ptr->shm_allocated == TRUE) {
        OPA_read_write_barrier();
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    }
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    /* free start group stored in window */
    MPIU_Free(win_ptr->start_ranks_in_win_grp);
    win_ptr->start_ranks_in_win_grp = NULL;

    win_ptr->posted_ops_cnt = 0;
    MPIU_Assert(win_ptr->active_req_cnt == 0);
    MPIU_Assert(win_ptr->start_req == NULL);
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    win_ptr->states.access_state = MPIDI_RMA_NONE;
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  fn_exit:
    MPIDI_RMA_FUNC_EXIT(MPID_STATE_MPIDI_WIN_COMPLETE);
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    return mpi_errno;
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    /* --BEGIN ERROR HANDLING-- */
  fn_fail:
    goto fn_exit;
    /* --END ERROR HANDLING-- */
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}
754

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#undef FUNCNAME
758
#define FUNCNAME MPIDI_Win_wait
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#undef FCNAME
#define FCNAME MPIDI_QUOTE(FUNCNAME)
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int MPIDI_Win_wait(MPID_Win * win_ptr)
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{
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    int mpi_errno = MPI_SUCCESS;
    MPIDI_STATE_DECL(MPID_STATE_MPIDI_WIN_WAIT);

    MPIDI_RMA_FUNC_ENTER(MPID_STATE_MPIDI_WIN_WAIT);
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    MPIU_ERR_CHKANDJUMP(win_ptr->states.exposure_state != MPIDI_RMA_PSCW_EXPO,
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                        mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");
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771
    /* wait for all operations from other processes to finish */
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    while (win_ptr->at_completion_counter) {
        mpi_errno = wait_progress_engine();
        if (mpi_errno != MPI_SUCCESS)
            MPIU_ERR_POP(mpi_errno);
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    }

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    /* Ensure ordering of load/store operations. */
    if (win_ptr->shm_allocated == TRUE) {
        OPA_read_write_barrier();
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    }

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    win_ptr->states.exposure_state = MPIDI_RMA_NONE;

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  fn_exit:
    MPIDI_RMA_FUNC_EXIT(MPID_STATE_MPIDI_WIN_WAIT);
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    return mpi_errno;
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    /* --BEGIN ERROR HANDLING-- */
  fn_fail:
    goto fn_exit;
    /* --END ERROR HANDLING-- */
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}

794

795
#undef FUNCNAME
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#define FUNCNAME MPIDI_Win_test
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#undef FCNAME
#define FCNAME MPIDI_QUOTE(FUNCNAME)
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int MPIDI_Win_test(MPID_Win * win_ptr, int *flag)
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{
    int mpi_errno = MPI_SUCCESS;
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    MPIDI_STATE_DECL(MPID_STATE_MPIDI_WIN_TEST);
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804
    MPIDI_RMA_FUNC_ENTER(MPID_STATE_MPIDI_WIN_TEST);
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806
    MPIU_ERR_CHKANDJUMP(win_ptr->states.exposure_state != MPIDI_RMA_PSCW_EXPO,
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                        mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");
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809 810
    mpi_errno = MPID_Progress_test();
    if (mpi_errno != MPI_SUCCESS) {
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	MPIU_ERR_POP(mpi_errno);
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    }

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    *flag = (win_ptr->at_completion_counter) ? 0 : 1;
    if (*flag) {
        /* Ensure ordering of load/store operations. */
        if (win_ptr->shm_allocated == TRUE) {
            OPA_read_write_barrier();
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        }
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        win_ptr->states.exposure_state = MPIDI_RMA_NONE;
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    }

824
  fn_exit:
825
    MPIDI_RMA_FUNC_EXIT(MPID_STATE_MPIDI_WIN_TEST);
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    return mpi_errno;
827
    /* --BEGIN ERROR HANDLING-- */
828
  fn_fail:
829
    goto fn_exit;
830
    /* --END ERROR HANDLING-- */
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}

833

834 835 836 837 838 839
/********************************************************************************/
/* Passive Target synchronization (including WIN_LOCK, WIN_UNLOCK, WIN_FLUSH,   */
/* WIN_FLUSH_LOCAL, WIN_LOCK_ALL, WIN_UNLOCK_ALL, WIN_FLUSH_ALL,                */
/* WIN_FLUSH_LOCAL_ALL, WIN_SYNC)                                               */
/********************************************************************************/

840
#undef FUNCNAME
841
#define FUNCNAME MPIDI_Win_lock
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#undef FCNAME
#define FCNAME MPIDI_QUOTE(FUNCNAME)
844
int MPIDI_Win_lock(int lock_type, int dest, int assert, MPID_Win * win_ptr)
845
{
846 847 848 849 850
    int made_progress = 0;
    int shm_target = FALSE;
    int rank = win_ptr->comm_ptr->rank;
    MPIDI_RMA_Target_t *target = NULL;
    MPIDI_VC_t *orig_vc = NULL, *target_vc = NULL;
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    int mpi_errno = MPI_SUCCESS;
852
    MPIDI_STATE_DECL(MPID_STATE_MPIDI_WIN_LOCK);
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854
    MPIDI_RMA_FUNC_ENTER(MPID_STATE_MPIDI_WIN_LOCK);
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    /* Note that here we cannot distinguish if this access epoch is overlapped
       with an access epoch of FENCE (which is not allowed), since FENCE may be
       ended up with not unsetting the window state. We can only detect if this
       access epoch is overlapped with another access epoch of PSCW or Passive
       Target. */
    if (win_ptr->lock_epoch_count == 0) {
        MPIU_ERR_CHKANDJUMP(win_ptr->states.access_state != MPIDI_RMA_NONE &&
                            win_ptr->states.access_state != MPIDI_RMA_FENCE_ISSUED &&
                            win_ptr->states.access_state != MPIDI_RMA_FENCE_GRANTED,
                            mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");
    }
    else {
        MPIU_ERR_CHKANDJUMP(win_ptr->states.access_state != MPIDI_RMA_NONE &&
                            win_ptr->states.access_state != MPIDI_RMA_FENCE_ISSUED &&
                            win_ptr->states.access_state != MPIDI_RMA_FENCE_GRANTED &&
                            win_ptr->states.access_state != MPIDI_RMA_PER_TARGET,
                            mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");
    }
874

875 876 877 878 879 880
    if (dest != MPI_PROC_NULL) {
        /* check if we lock the same target window more than once. */
        mpi_errno = MPIDI_CH3I_Win_find_target(win_ptr, dest, &target);
        if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
        MPIU_ERR_CHKANDJUMP(target != NULL, mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");
    }
881

882
    /* Error handling is finished. */
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884 885 886 887 888
    if (win_ptr->lock_epoch_count == 0) {
        win_ptr->states.access_state = MPIDI_RMA_PER_TARGET;
        num_passive_win++;
    }
    win_ptr->lock_epoch_count++;
889

890 891
    if (dest == MPI_PROC_NULL)
        goto fn_exit;
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893 894 895 896 897
    if (win_ptr->shm_allocated == TRUE) {
        MPIDI_Comm_get_vc(win_ptr->comm_ptr, rank, &orig_vc);
        MPIDI_Comm_get_vc(win_ptr->comm_ptr, dest, &target_vc);
        if (orig_vc->node_id == target_vc->node_id)
            shm_target = TRUE;
898
    }
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900 901 902
    /* Create a new target. */
    mpi_errno = MPIDI_CH3I_Win_create_target(win_ptr, dest, &target);
    if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
903

904 905 906 907 908 909 910 911 912 913 914 915 916 917
    /* Store lock_state (CALLED/ISSUED/GRANTED), lock_type (SHARED/EXCLUSIVE),
       lock_mode (MODE_NOCHECK). */
    if (assert & MPI_MODE_NOCHECK)
        target->access_state = MPIDI_RMA_LOCK_GRANTED;
    else
        target->access_state = MPIDI_RMA_LOCK_CALLED;
    target->lock_type = lock_type;
    target->lock_mode = assert;

    /* If Destination is myself or process on SHM, acquire the lock,
       wait until lock is granted. */
    if (!(assert & MPI_MODE_NOCHECK) && (dest == rank || shm_target)) {
        mpi_errno = MPIDI_CH3I_RMA_Make_progress_target(win_ptr, dest, &made_progress);
        if (mpi_errno != MPI_SUCCESS)
918 919
            MPIU_ERR_POP(mpi_errno);

920 921 922
        while (target->access_state != MPIDI_RMA_LOCK_GRANTED) {
            mpi_errno = wait_progress_engine();
            if (mpi_errno != MPI_SUCCESS)
923
                MPIU_ERR_POP(mpi_errno);
924
        }
925
    }
926

927 928 929
    /* Ensure ordering of load/store operations. */
    if (win_ptr->shm_allocated == TRUE) {
        OPA_read_write_barrier();
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    }

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  fn_exit:
    MPIDI_RMA_FUNC_EXIT(MPID_STATE_MPIDI_WIN_LOCK);
    return mpi_errno;
    /* --BEGIN ERROR HANDLING-- */
  fn_fail:
    goto fn_exit;
    /* --END ERROR HANDLING-- */
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}

#undef FUNCNAME
942
#define FUNCNAME MPIDI_Win_unlock
943 944
#undef FCNAME
#define FCNAME MPIDI_QUOTE(FUNCNAME)
945
int MPIDI_Win_unlock(int dest, MPID_Win *win_ptr)
946
{
947 948 949 950
    int made_progress = 0;
    int local_completed = 0, remote_completed = 0;
    MPIDI_RMA_Target_t *target = NULL;
    enum MPIDI_RMA_sync_types sync_flag;
951
    int mpi_errno = MPI_SUCCESS;
952
    MPIDI_STATE_DECL(MPID_STATE_MPIDI_WIN_UNLOCK);
953

954
    MPIDI_RMA_FUNC_ENTER(MPID_STATE_MPIDI_WIN_UNLOCK);
955

956
    MPIU_ERR_CHKANDJUMP(win_ptr->states.access_state != MPIDI_RMA_PER_TARGET,
957
                        mpi_errno, MPI_ERR_RMA_SYNC, "**rmasync");
958

959
    /* Ensure ordering of load/store operations. */
960
    if (win_ptr->shm_allocated) {
961 962
        OPA_read_write_barrier();
    }
963

964 965 966 967 968 969 970 971 972 973 974 975 976
    if (dest == MPI_PROC_NULL)
        goto finish_unlock;

    /* When the process tries to acquire the lock on itself, it does not
       go through the progress engine. Therefore, it is possible that
       one process always grants the lock to itself but never process
       events coming from other processes. This may cause deadlock in
       applications where the program execution on target process depends
       on the happening of events from other processes. Here we poke
       the progress engine once to avoid such issue.  */
    mpi_errno = poke_progress_engine();
    if (mpi_errno != MPI_SUCCESS)
        MPIU_ERR_POP(mpi_errno);
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978 979 980 981 982 983 984
    /* Find or recreate target. */
    mpi_errno = MPIDI_CH3I_Win_find_target(win_ptr, dest, &target);
    if (mpi_errno != MPI_SUCCESS)
        MPIU_ERR_POP(mpi_errno);
    if (target == NULL) {
        mpi_errno = MPIDI_CH3I_Win_create_target(win_ptr, dest, &target);
        if (mpi_errno != MPI_SUCCESS)
985
            MPIU_ERR_POP(mpi_errno);
986
        target->access_state = MPIDI_RMA_LOCK_GRANTED;
987 988
    }

989 990 991 992 993 994 995 996 997
    /* Set sync_flag in sync struct. */
    if (target->lock_mode & MPI_MODE_NOCHECK)
        sync_flag = MPIDI_RMA_SYNC_FLUSH;
    else
        sync_flag = MPIDI_RMA_SYNC_UNLOCK;
    if (target->sync.sync_flag < sync_flag) {
        target->sync.sync_flag = sync_flag;
        target->sync.have_remote_incomplete_ops = 0;
        target->sync.outstanding_acks++;
998
    }
999

1000 1001 1002 1003 1004
    /* Issue out all operations. */
    mpi_errno = MPIDI_CH3I_RMA_Make_progress_target(win_ptr, dest,
                                                    &made_progress);
    if (mpi_errno != MPI_SUCCESS)
        MPIU_ERR_POP(mpi_errno);
1005

1006 1007 1008 1009 1010 1011 1012 1013 1014 1015
    /* Wait for remote completion. */
    do {
        mpi_errno = MPIDI_CH3I_RMA_Cleanup_ops_target(win_ptr, target,
                                                      &local_completed,
                                                      &remote_completed);
        if (mpi_errno != MPI_SUCCESS)
            MPIU_ERR_POP(mpi_errno);
        if (!remote_completed) {
            mpi_errno = wait_progress_engine();
            if (mpi_errno != MPI_SUCCESS)
1016
                MPIU_ERR_POP(mpi_errno);
1017
        }
1018
    } while (!remote_completed);
1019

1020 1021 1022
    /* Cleanup the target. */
    mpi_errno = MPIDI_CH3I_RMA_Cleanup_single_target(win_ptr, target);
    if (mpi_errno != MPI_SUCCESS) MPIU_ERR_POP(mpi_errno);
1023

1024 1025 1026
 finish_unlock:
    win_ptr->posted_ops_cnt = 0;
    MPIU_Assert(win_ptr->active_req_cnt == 0);
1027

1028 1029 1030 1031 1032 1033
    win_ptr->lock_epoch_count--;
    if (win_ptr->lock_epoch_count == 0) {
        win_ptr->states.access_state = MPIDI_RMA_NONE;
        num_passive_win--;
        MPIU_Assert(num_passive_win >= 0);
    }
1034

1035
  fn_exit:
1036
    MPIDI_RMA_FUNC_EXIT(MPID_STATE_MPIDI_WIN_UNLOCK);
1037
    return mpi_errno;
1038
    /* --BEGIN ERROR HANDLING-- */
1039
  fn_fail:
1040
    goto fn_exit;